Advanced Hydrogen Transport Membranes for Vision 21 Fossil Fuel Plants | Zendy

Carl R. Evenson | Zendy; H. Wright | Zendy; Adam E. Calihman | Zendy; U. Balachandran | Zendy; Richard N. Kleiner | Zendy; James E. Stephan | Zendy; Frank E. Anderson | Zendy; Chandra Ratnasamy | Zendy; Mahendra K. Sunkara | Zendy; Jyothish Thangala | Zendy; Clive Brereton | Zendy; Warren Wolfs | Zendy; James Lockhart | Zendy

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Advanced Hydrogen Transport Membranes for Vision 21 Fossil Fuel Plants

Author(s) -

Carl R. Evenson,

H. Wright,

Adam E. Calihman,

U. Balachandran,

Richard N. Kleiner,

James E. Stephan,

Frank E. Anderson,

Chandra Ratnasamy,

Mahendra K. Sunkara,

Jyothish Thangala,

Clive Brereton,

Warren Wolfs,

James Lockhart

Publication year - 2005

Language(s) - English

Resource type - Reports

DOI - 10.2172/860438

Subject(s) - hydrogen , membrane , permeation , materials science , dissociation (chemistry) , chemical engineering , permeability (electromagnetism) , sintering , sulfur , cermet , chemistry , composite material , engineering , organic chemistry , metallurgy , ceramic , biochemistry

During this quarter composite layered membrane size was scaled-up and tested for permeation performance. Sintering conditions were optimized for a new cermet containing a high permeability metal and seals were developed to allow permeability testing. Theoretical calculations were performed to determine potential sulfur tolerant hydrogen dissociation catalysts. Finally, work was finalized on mechanical and process & control documentation for a hydrogen separation unit

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